Methods and apparatus for color signal compensation are disclosed. A quality of one type of signal is enhanced using a second type of signal, wherein the second type of signal has a higher quality than that of the unenhanced first type of signal. This may be used in an image forming apparatus for scanning a color image, and using higher-resolution monochrome signals to enhance the resolution of lower-resolution color signals.
Legal claims defining the scope of protection, as filed with the USPTO.
1. An image reading apparatus, comprising an image sensor unit comprising a first photoconverter comprising a first array of first light receiving elements, the first photoconverter for photoelectrically converting light of a first color from a source image for outputting a first color signal a second photoconverter comprising a second array of second light receiving elements, the second photoconverter for photoelectrically converting light of a second color from a source image for outputting a second color signal a third photoconverter comprising a third array of third light receiving elements, the third photoconverter for photoelectrically converting light of a third color from a source image for outputting a third color signal a fourth photoconverter comprising a fourth array of fourth light receiving elements, the fourth photoconverter for photoelectrically converting monochromatic light from the source image for outputting a monochrome signal an A/D converter unit to convert the first, second, and third color signals into respective first, second, and third digitized color signals each having a first number of bits convert the monochrome signal to a digitized monochrome signal having a second number of bits greater than the first number of bits a signal correction unit to produce enhanced color signals use the digitized monochrome signal to modify the first, second, and third digitized color signals to produce the enhanced color signals.
2. The image reading apparatus of claim 1 wherein the enhanced color signals comprise first, second, and third digitized enhanced color signals, each having the second number of bits.
3. The image reading apparatus of claim 1 wherein the signal correction unit is for improving the color signals' gradation.
4. The image reading apparatus of claim 3 wherein the signal correction unit is further for improving the color signals' resolution.
5. The image reading apparatus of claim 1 wherein the color signals are signals of three primary colors.
6. The image reading apparatus of claim 5 wherein the first color is red, the second color is green and the third color is blue.
7. The image reading apparatus of claim 6 , wherein the signal coffection unit is adapted to obtain a brightness signal from the digitized monochrome signal obtain a first color difference signal from the first, second and third digitized color signals obtain a second color difference signal from the first, second and third digitized color signals obtain enhanced first, second, and third color image signals from the brightness signal and the first and second color difference signals.
8. An image reading apparatus comprising an image sensor unit comprising a first photoconverter comprising a first array of first light receiving elements, the first photoconverter for photoelectrically converting light of a first color from a source image for outputting a first color signal a second photoconverter comprising a second array of second light receiving elements, the second photoconverter for photoelectrically converting light of a second color from a source image for outputting a second color signal a third photoconverter comprising a third array of third light receiving elements, the third photoconverter for photoelectrically converting light of a third color from a source image for outputting a third color signal a fourth photoconverter comprising a fourth away of fourth light receiving elements, the fourth photoconverter for photoelectrically converting monochromatic light from the source image for outputting a plurality of monochrome signals an A/D converter unit to convert the first, second, and third color signals into respective first, second, and third digitized color signals each having a first number of bits convert the plurality of monochrome signals to digitized monochrome signals each having a second number of bits greater than the first number of bits a signal collection unit to produce enhanced color signals use the plurality of monochrome signals to modify the first, second, and third digitized color signals to produce the enhanced color signals.
9. The image reading apparatus of claim 8 , wherein the enhanced color signals comprise first, second, and third digitized enhanced color signals, each having the second number of bits.
10. The image reading apparatus of claim 8 , wherein the signal correction unit is for improving the color signals' gradation.
11. The image reading apparatus of claim 10 wherein the signal correction unit is further for improving the color signals' resolution.
12. The image reading apparatus of claim 8 , wherein the color signals are signals of three primary colors.
13. The image reading apparatus of claim 12 , wherein the first color is red, the second color is green and the third color is blue.
14. The image reading apparatus of claim 13 , wherein the signal correction unit is adapted to obtain brightness signals from the digitized monochrome signals obtain a first color difference signal from the first, second and third digitized color signals obtain a second color difference signal from the first, second and third digitized color signals obtain-enhanced first, second, and third color image signals from the brightness signals and the first and second color difference signals.
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March 9, 2004
August 14, 2007
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